This lesson plan teaches how to select the landing site for a planetary surface investigation, using the 5E learning cycle. Students will be able to determine a landing site for their Mars rover; work with their team to summarize information and...(View More) identify important details in non-fiction writing; research Gale Crater through an online interactive module; use Google Earth Mars to learn about Mars surface features; gather and analyze data to conduct a scientific experiment; collect and record data in a science notebook to draw logical and scientific conclusions; define and identify the role of controls and variables in teams' scientific or technical questions; and differentiate between weather and climate. The lesson plan has a number of appendices, including standards alignment. This is Lesson 8 of the elementary school version of the 6 week Mars Rover Celebration curriculum.(View Less)

This collection of 160 math problems covers the 20 science topic themes presented by the NASA/JPL Year of the Solar System (YOSS) website, covering the solar system, planets, the search for life, and robotics. Examples of topics included are: scale...(View More) of the solar system; asteroids; comets; moons and rings; volcanism in the solar system; ice in the solar system; water in the solar system; the Sun, transits and eclipses; astrobiology; magnetosphers and more. It is intended as a mathematics supplement for the science content presented at the YOSS website, and features grade-appropriate and Common Core State Standards-based math problems based on science content for grades 3-12.(View Less)

This is a set of one-page problems about the size and area of solar panels used to generate power. Learners will calculate area fractions to compare the sizes and distances of Jupiter's moons. Options are presented so that students may learn about...(View More) the Juno mission through a NASA press release or about how solar energy is used by various NASA satellites and technology by viewing a NASA eClips™ video [3 min]. Common Core State Standards for Mathematics and English Language Arts are identified. This activity is part of the Space Math multi-media modules that integrate NASA press releases, NASA archival video, and mathematics problems targeted at specific math standards commonly encountered in middle school.(View Less)

This is a set of one-page problems about the sizes of moons in the solar system. Learners will use decimals to compare the sizes and distances of Saturn's moons to the center of Saturn. Options are presented so that students may learn about the...(View More) Cassini mission through a NASA press release or by viewing a NASA eClips™ video [4 min.] about these and other moons in our solar system. Common Core State Standards for Mathematics and English Language Arts are identified. This activity is part of the Space Math multi-media modules that integrate NASA press releases, NASA archival video, and mathematics problems targeted at specific math standards commonly encountered in middle school.(View Less)

This book contains 24 illustrated math problem sets based on a weekly series of space science problems. Each set of problems is contained on one page. The problems were created to be authentic glimpses of modern science and engineering issues, often...(View More) involving actual research data. Learners will use mathematics to explore problems that include basic scales and proportions, fractions, scientific notation, algebra, and geometry.(View Less)

This is an activity about the Signal-to-Noise Ratio. Learners will engage with a hands-on activity and an online interactive to understand the terms signal and noise as they relate to spacecraft communication; quantify noise using a given dataset;...(View More) and calculate the signal-to-noise ratio. The activity also includes a pencil-and-paper component that addresses relevant topics, such as proportions and ratios. Includes teacher background information, student data sheets, answer guide, extensions and adaptions.(View Less)

Learners will use data from the Student Dust Counter (SDC) Data Viewer to establish any trends in the distribution of dust in the solar system. Students record the number of dust particles, or hits, recorded by the instrument and the average mass of...(View More) the particles in a given region. Note: Updated links to the Student Dust Counter Data Viewer and website are provided under Related & Supplemental Resources (right).(View Less)

Learners will relate the concept of density to the density of dust in space. They will use mission data from the Student Dust Counter (SDC) data viewer to determine the density of dust grains in a volume of space in order to answer questions...(View More) concerning the distribution of dust in the solar system. They will discover that space is much more sparsely populated with dust than they may have thought. Students discuss their findings with the class. Note: Updated links to the Student Dust Counter Data Viewer and website are provided under Related & Supplemental Resources (right).(View Less)

Using a graphing calculator and a Norland Research calculator robot, students create programs in TI-BASIC to direct their robot through a variety of tasks. Ten robot missions and three exploration extensions are included in this lesson booklet....(View More) Beginning missions include step-by-step programming instructions; the missions become increasingly challenging throughout.(View Less)

This activity is about the discovery of water ice on Mars. Learners will record and graph temperature data and use a model of an ice-rich and ice-free surface on Mars to examine how ice content in the martian soil would impact the temperature of a...(View More) Mars microbe after impact. A student information sheet introducing the subject of ice and the search for water on Mars is provided. The activity requires access to a freezer the night before the activity. Note: Find the latest information and updates on Mars missions at the NASA Mars Exploration website (see Related & Supplemental Resources to the right).(View Less)